Patent application number | Description | Published |
20090111267 | METHOD OF ANTI-STICTION DIMPLE FORMATION UNDER MEMS - A method for making a MEMS structure comprises patterning recesses in a dielectric layer overlying a substrate, each recess being disposed between adjacent mesas of dielectric material. A conformal layer of semiconductor material is formed overlying the recesses and mesas. The conformal layer is chemical mechanically polished to form a chemical mechanical polished surface, wherein the chemical mechanical polishing is sufficient to create dished portions of semiconductor material within the plurality of recesses. Each dished portion has a depth proximate a central portion thereof that is less than a thickness of the semiconductor material proximate an outer portion thereof. A semiconductor wafer is then bonded to the chemical mechanical polished surface. The bonded semiconductor wafer is patterned with openings according to the requirements of a desired MEMS transducer. Lastly, the MEMS transducer is released. Releasing advantageously exposes anti-stiction features formed from outer edges of the dished portion of semiconductor material. | 04-30-2009 |
20100244159 | EUTECTIC FLOW CONTAINMENT IN A SEMICONDUCTOR FABRICATION PROCESS - Eutectic Flow Containment in a Semiconductor Fabrication Process A disclosed semiconductor fabrication process includes forming a first bonding structure on a first surface of a cap wafer, forming a second bonding structure on a first surface of a device wafer, and forming a device structure on the device wafer. One or more eutectic flow containment structures are formed on the cap wafer, the device wafer, or both. The flow containment structures may include flow containment micro-cavities (FCMCs) and flow containment micro-levee (FCMLs). The FCMLs may be elongated ridges overlying the first surface of the device wafer and extending substantially parallel to the bonding structure. The FCMLs may include interior FCMLs lying within a perimeter of the bonding structure, exterior FCMLs lying outside of the bonding structure perimeter, or both. When the two wafers are bonded, the FCMLs and FCMCs confine flow of the eutectic material to the region of the bonding structure. | 09-30-2010 |
20110042761 | EUTECTIC FLOW CONTAINMENT IN A SEMICONDUCTOR FABRICATION PROCESS - A disclosed semiconductor fabrication process includes forming a first bonding structure on a first surface of a cap wafer, forming a second bonding structure on a first surface of a device wafer, and forming a device structure on the device wafer. One or more eutectic flow containment structures are formed on the cap wafer, the device wafer, or both. The flow containment structures may include flow containment micro-cavities (FCMCs) and flow containment micro-levee (FCMLs). The FCMLs may be elongated ridges overlying the first surface of the device wafer and extending substantially parallel to the bonding structure. The FCMLs may include interior FCMLs lying within a perimeter of the bonding structure, exterior FCMLs lying outside of the bonding structure perimeter, or both. When the two wafers are bonded, the FCMLs and FCMCs confine flow of the eutectic material to the region of the bonding structure. | 02-24-2011 |
20120001277 | METHODS FOR MAKING IN-PLANE AND OUT-OF-PLANE SENSING MICRO-ELECTRO-MECHANICAL SYSTEMS (MEMS) - A device structure is made using a first conductive layer over a first wafer. An isolated conductive region is formed in the first conductive layer surrounded by a first opening in the conductive layer. A second wafer has a first insulating layer and a conductive substrate, wherein the conductive substrate has a first major surface adjacent to the first insulating layer. The insulating layer is attached to the isolated conductive region. The conductive substrate is thinned to form a second conductive layer. A second opening is formed through the second conductive layer and the first insulating layer to the isolated conductive region. The second opening is filled with a conductive plug wherein the conductive plug contacts the isolated conductive region. The second conductive region is etched to form a movable finger over the isolated conductive region. A portion of the insulating layer under the movable finger is removed. | 01-05-2012 |
20120042731 | MEMS Pressure Sensor Device and Method of Fabricating Same - A microelectromechanical systems (MEMS) pressure sensor device ( | 02-23-2012 |
20120043627 | MEMS Sensor Device With Multi-Stimulus Sensing and Method of Fabricating Same | 02-23-2012 |
20120107992 | METHOD OF PRODUCING LAYERED WAFER STRUCTURE HAVING ANTI-STICTION BUMPS | 05-03-2012 |
20120175747 | MEMS DEVICE ASSEMBLY AND METHOD OF PACKAGING SAME - An assembly ( | 07-12-2012 |
20120256282 | MEMS SENSOR DEVICE WITH MULTI-STIMULUS SENSING | 10-11-2012 |
20130043564 | ATTACHING A MEMS TO A BONDING WAFER - A MEMS is attached to a bonding wafer in part by forming a support layer over the MEMS. A first eutectic layer is formed over the support layer. The eutectic layer is patterned into segments to relieve stress. A second eutectic layer is formed over the bonding wafer. A eutectic bond is formed with the segments and the second eutectic layer to attach the bonding wafer to the MEMS. | 02-21-2013 |
20130285161 | INTEGRATED CIRCUIT HAVING VARYING SUBSTRATE DEPTH AND METHOD OF FORMING SAME - A semiconductor device is formed such that a semiconductor substrate of the device has a non-uniform thickness. A cavity is etched at a selected side of the semiconductor substrate, and the selected side is then fusion bonded to another substrate, such as a carrier substrate. After fusion bonding, the side of the semiconductor substrate opposite the selected side is ground to a defined thickness. Accordingly, the semiconductor substrate has a uniform thickness except in the area of the cavity, where the substrate is thinner. Devices that benefit from a thinner substrate, such as an accelerometer, can be formed over the cavity. | 10-31-2013 |